The Frequency of Fitness Peak Shifts Is Increased at Expanding Range Margins Due to Mutation Surfing

Burton, Olivia J.; Travis, Justin M. J.

doi:10.1534/genetics.108.087890

Cited by 47 publications

(57 citation statements)

References 56 publications

(72 reference statements)

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“…An increasing number of simulation studies are investigating the dynamics and spatial spread of neutral mutations that occur during a period of range expansion (Ibrahim et al, 1996;Austerlitz and Garnier-Géré, 2003;Edmonds et al, 2004;Bialozyt et al, 2006;Klopfstein et al, 2006) but, to date, far less works have considered the fate of non-neutral mutations. It has recently been demonstrated that the surfing phenomenon observed by Edmonds et al (2004) and Klopfstein et al (2006) is likely to lead to the substantially increased survival and spread of deleterious mutants at the front Burton and Travis, 2008), and the results presented here corroborate with those results. Whereas previous works have focussed on using a centroid statistic to describe spread, here we have used spatial extent (as measured by the number of patches occupied) and total population size, in addition to looking at the maximum x-displacement obtained by a surviving mutation.…”

Section: Oj Burton and Jmj Travissupporting

confidence: 90%

“…Second, with absorbing boundary conditions, the leading edge of the range expansion is most often away from the edge towards the centre of the lattice (Figure 4a), which is due to additional mortality at absorbing edges leading to less rapid population growth. Mutations are most likely to survive when they occur at, or very close to, the leading edge, as it is only then that they and their descendants are most likely to remain at the front and benefit from reduced competition (Klopfstein et al, 2006;Travis et al, 2007;Burton and Travis, 2008). The first of these effects applies equally to mutations regardless of their fitness effect, but the second has a much greater influence on deleterious mutations, as their survival is much more dependent on them surfing the expanding wave front than it is for neutral or beneficial mutations.…”

Section: Discussionmentioning

confidence: 99%

“…This model is an extension of recent studies investigating the dynamics of neutral (Edmonds et al, 2004;Klopfstein et al, 2006) and nonneutral Burton and Travis, 2008) mutations arising at expanding range margins. Here, we consider the effects of employing different boundary conditions and the position of a mutation's origin on the fate and distribution of both neutral mutations and those that alter the relative fitness of individuals.…”

Section: The Modelmentioning

confidence: 98%

“…Mutants, regardless of fitness effect, arising close to the front sometimes surf to high frequency and spatial extent Burton and Travis, 2008). The survival probability of deleterious mutations occurring on the front of an expanding range can be relatively high, up to nearly 20% (Figure 3a), and is conditional on this surfing behaviour.…”

Section: Survival and Dynamics Of Mutantsmentioning

confidence: 99%

“…Travis et al (2007) also showed that the spatial distribution of a surviving mutant differs considerably depending on its fitness effect, with most surviving beneficial mutations having their centroid close to where they originated, whereas most surviving deleterious mutations have a spatial distribution concentrated close to the expanding front. In a further recent extension, Burton and Travis (2008) developed a two-locus model, incorporating sign epistasis, and demonstrated that fitness peak shifts are more likely during range expansion due to the importance of this surfing effect for the survival and abundance of deleterious mutations. Here, we extend the methods used by Travis et al (2007) to consider how surfing dynamics are influenced by landscape structure.…”

Section: Introductionmentioning

confidence: 99%

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Landscape structure and boundary effects determine the fate of mutations occurring during range expansions

Burton

Travis

2008

Heredity

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The interplay between the spatial dynamics of range expansion and evolutionary processes is receiving considerable attention. Recent theory has demonstrated that mutations occurring towards the front of a spatially expanding population can sometimes 'surf' to high frequency and spatial extent. Here, we extend this work to consider how the fate of a novel mutation is influenced by where and when it occurs. Specifically, we are interested in establishing how the origin of a mutation relative to a habitat edge influences its dynamics, and in understanding how this is mediated by the behaviour of individuals at those boundaries. Using a coupled-map lattice model, we demonstrate that the survival probability, abundance and spatial extent of surviving mutants can depend on their origin. An edge effect is often observed and can be quite different both qualitatively and quantitatively depending on the behavioural rules assumed. Mutations, especially those that are deleterious, that arise at a habitat edge with reflective boundary conditions can be many more times likely to survive for substantial periods of time than those that arise away from the edge. Conversely, with absorbing boundary conditions, their survival is greater when they arise well away from the edge. Our results clearly illustrate that landscape structure, habitat edges and boundary conditions have a considerable influence on the likely fate of mutations that occur during a period of range expansion.

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Section: Oj Burton and Jmj Travissupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: The Modelmentioning

confidence: 98%

Section: Survival and Dynamics Of Mutantsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Landscape structure and boundary effects determine the fate of mutations occurring during range expansions

Burton

Travis

2008

Heredity

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Expansion Load

Peischl

Excoffier

2016

Invasion Genetics

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Expanding populations incur a mutation burden -the so-called expansion load. Previous studies of expansion load have focused on co-dominant mutations. An important consequence of this assumption is that expansion load stems exclusively from the accumulation of new mutations occurring in individuals living at the wave front. Using individual-based simulations we study here the dynamics of standing genetic variation at the front of expansions, and its consequences on mean fitness if mutations are recessive. We find that deleterious genetic diversity is quickly lost at the front of the expansion, but the loss of deleterious mutations at some loci is compensated by an increase of their frequencies at other loci. The frequency of deleterious homozygotes therefore increases along the expansion axis whereas the average number of deleterious mutations per individual remains nearly constant across the species range. This reveals two important differences to co-dominant models: (i) mean fitness at the front of the expansion drops much faster if mutations are recessive, and (ii) mutation load can increase during the expansion even if the total number of deleterious mutations per individual remains constant. We use our model to make predictions about the shape of the site frequency spectrum at the front of range expansion, and about correlations between heterozygosity and fitness in different parts of the species range. Importantly, these predictions provide opportunities to empirically validate our theoretical results. We discuss our findings in the light of recent results on the distribution of deleterious genetic variation across human populations, and link them to empirical results on the correlation of heterozygosity and fitness found in many natural range expansions.

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